Paramecium

P your mom aramecia
	Paramecium aurelia
Scientific classification
Domain:	Eukaryota
Kingdom:	Protista
Phylum:	Chlorophora
Class:	Ciliatea
Order:	Peniculida
Family:	Parameciidae
Genus:	Paramecia; Müller, 1773
Species
	Paramecium aurelia; Paramecium bursaria; Paramecium caudatum; =0 =) parecu\ium

Paramecia are a group of unicellular ciliate protozoa, which are commonly studied as a representative of the ciliate group, and range from about 50 to 350 μm in length, Simple cilia cover the body, which allow the cell to move with a synchronous motion (like a caterpillar). There is also a deep oral groove containing inconspicuous compound oral cilia (as found in other peniculids) used to draw food inside. They generally feed on bacteria and other small cells. Osmoregulation is carried out by a pair of contractile vacuoles, which actively expel water absorbed by osmosis from their surroundings.

Paramecia are widespread in freshwater environments, and are especially common in scums. Paramecia are attracted by acidic conditions. Certain single-celled eukaryotes, such as Paramecium, are examples for exceptions to the universality of the genetic code (translation systems where a few codons differ from the standard ones).

Physiology

The paramecium approximates a prolate spheroid^[1], rounded at the front and pointed at the back. The pellicle is a stiff but elastic membrane that gives the paramecium its definite shape. Covering the pellicle are many tiny hairs, called cilia. On the side beginning near the front end continuing down half way is the oral groove, which collects food until it is swept into the cell mouth. There is an opening near the back end called the anal glup pore. The contractile vacuole and its radiating canals — referred to previously for osmoregulation of the organism, are also found on the outside of a paramecium.

The paramecium contains cytoplasm, trichocysts (“thread capsules”), the gullet, food vacuoles, the macronucleus, and the micronucleus.

Locomotion

For the paramecium to move forward, its cilia beat on an angle, backward. This means that the paramecium moves by spiralling through the water on an invisible axis. For the paramecium to move backward, the cilia simply beat forward on an angle.

If the paramecium runs into a solid object, the cilia changes its direction and beats forward, causing the paramecium to go backward. The paramecium turns slightly and goes forward again. If it runs into the solid object again it will repeat this process until it can get past the object.

Gathering food

Paramecia feed on microorganisms like bacteria, algae, and yeasts. To gather its food, the paramecium uses its cilia to sweep the food along with some water into the cell mouth after it falls into the oral groove. The food goes through the cell mouth into the gullet, which is like the stomach. When enough food has accumulated at the gullet base, it navigates there to form a food vacuole in the cytoplasm, and travels through the cell, through the back end first. As it moves along, enzymes from the cytoplasm enter the vacuole to digest the contents, digested nutrients then going into the cytoplasm, and the vacuole shrinks. When the vacuole reaches the anal pore, it ruptures, expelling its waste contents to the exterior.

Symbiosis

One of the most interesting known symbiotic relationships is that of Paramecium aurelia and its bacterial endosymbionts. The bacteria infect the protozoa, and they produce toxic particles that kill sensitive strains, but not killer strains. See also the Chlorella symbiosis with Paramecium bursaria.

Giant amoebas, for instance, have types of endosymbiotes, which seem to function as mitochondria in these amoebas. Another example involves protozoa bacteria that produce cellulases to assist the host protozoan with cellulose digestion (similar to those found in some in termites). This is a cell that appears at quiet ponds.

Genome

The paramecium genome has been sequenced (species: Paramecium tetraurelia), providing evidence for three whole-genome duplication.^[2]

In some ciliates, like Stylonychia and Paramecium, only UGA decoded as a stop codon, while UAG and UAA are reassigned as sense codons.^[3]

Learning

The question of whether paramecia exhibit learning has been the object of a great deal of experiment, yielding equivocal results. In one of the most recent experiments published^[4], the authors, by using a voltage as a reinforcement, concluded that paramecium may indeed learn to discriminate between different brightness levels.

References

^ O. F. Muller [1]
^ Aury, J. M., O. Jaillon, et al. (2006). "Global trends of whole-genome duplications revealed by the ciliate Paramecium tetraurelia." Nature 444(7116): 171-8. [2]
^ Lekomtsev, S, Kolosov, P., et al. (2007) "Different modes of stop codon restriction by the Stylonychia and Paramecium eRF1 translation termination factors", PNAS, 104(26):10824-9 [3]
^ Armus, H.L., Montgomery, A.R., Jellison, J.L. (2006) "Discrimination Learning in Paramecia (P. caudatum)" , The Psychological Record, 56,489-498[4]

[1] O. F. Muller [1]

[2] Aury, J. M., O. Jaillon, et al. (2006). "Global trends of whole-genome duplications revealed by the ciliate Paramecium tetraurelia." Nature 444(7116): 171-8. [2]

[3] Lekomtsev, S, Kolosov, P., et al. (2007) "Different modes of stop codon restriction by the Stylonychia and Paramecium eRF1 translation termination factors", PNAS, 104(26):10824-9 [3]

[4] Armus, H.L., Montgomery, A.R., Jellison, J.L. (2006) "Discrimination Learning in Paramecia (P. caudatum)" , The Psychological Record, 56,489-498[4]

[1]

[2]

[3]

[4]