Complex Community in a Simple Habitat: An Experimental Study with Bacteria and Phage

• Published in: Ecology (Durham) Vol. 58; no. 2; pp. 369 - 378
• Format: Journal Article
• Language: English
• Published: Ecological Society of America 01.03.1977
• ISSN: 0012-9658; 1939-9170
• DOI: 10.2307/1935611

Continuous culture populations of the bacterium especially coli and its virulent virus T7 have been studied as a model of a predator—prey in a simple habitat. These organisms maintain apparently stable states of coexistence in: (1) a phage—limited situation where all of the bacteria are sensitive to the coexisting virus and the sole, and potentially limiting carbon source, glucose, is present in excess; and (2) a resource—limited situation where the majority of the bacteria are resistant to these phage and in which there is little free glucose. The composition of these interacting populations is examined in detail and evidence indicating that this simple experimental culture system can support relatively complex communities is presented. In the predator—limited situation, two populations at each of two trophic levels can be maintained; the wild—type bacterial and phage strains, denoted B₀ and T7₀, a mutant bacterial clone which is resistant to T7₀, denote B₁ and a host range mutant phage, T7₁ which is capable of growth on both B₀ and B₁. In the resource—limited situation, three populations of bacteria and two populations of phage can coexist. The include the above described clones and a third bacterial strain, B₂, which is resistant to both T7₀ and T7₁. In phage—free competition, the wild—type B₀ bacterial clone has a marked advantage relative to both B₁ and B₂ while no difference is detected between B₁ and B₂. When competing for a B₀ host, the wild—type T7₀ phage clone has a marked advantage over T7₁. The fit of these observations to some previously developed theory of resource—limited growth, competition and predation is discussed and a mechanism to account for the persistence of these communities is presented. The latter assumes that their stability can be attributed solely to intrinsic factors, i.e., the population growth and interaction properties of the organisms in this continuous culture habitat.